An endoscope has a first bending portion and a second bending portion. The first bending portion is the distal portion of an elongated insertion member, and the second bending portion is located at the proximal end of the first bending portion. The dimension of the second bending portion in the longitudinal axis of the insertion member is smaller than the dimension of the first bending portion therein. The endoscope includes a hand-held unit having a control section that is used to bend the first bending portion and second bending portion. The control section of the hand-held unit has an angling knob that is used to bend the first bending portion, and a second angling lever that is used to bend the second bending portion.
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23. An endoscope comprising:
a first bending portion that is the distal portion of an elongated insertion member, the first bending portion being bendable in accordance with the bending operation by a user; and a second bending portion that is located at the proximal end of the first bending portion and whose dimension in the longitudinal direction of the insertion member is larger than that of the first bending portion, the second bending portion being bendable in accordance with the bending operation by a user.
24. An endoscope comprising:
a first bending portion that is the distal portion of an elongated insertion member; a second bending portion that is located at the proximal end of said first bending portion and whose dimension in the longitudinal direction of said insertion member is larger than the dimension of the first bending portion therein; a first control portion included in a hand-held unit proximal to said insertion member and used to bend said first bending portion; and a second control portion included in the hand-held unit proximal to said insertion member and used to bend said second bending portion.
37. An endoscope comprising:
a first bending portion that is the distal portion of an elongated insertion member, the first bending portion being bendable in accordance with the bending operation by a user; and a second bending portion that is located at the proximal end of said bending portion, the second bending portion being bendable in accordance with the bending operation by the user, wherein said second bending portion has its length different from that of said first bending portion and a bending angle said first bending portion assumes when bent is set and a bending angle said second bending portion assumes when bent is set are determined so that when said second bending portion is bent by an angle θ and said first bending portion is bent by an angle θ90°C or more in a direction opposite to the direction in which said second bending portion is bent, if the distal portion of said insertion member is angled substantially perpendicularly to the longitudinal direction of said insertion member, the distal portion of said insertion member will be distanced from a tangent to the longitudinal direction of said insertion member.
1. An endoscope comprising:
a first bending portion that is the distal portion of an elongated insertion member, the first bending portion being bendable in accordance with the bending operation by a user; and a second bending portion that is located at the proximal end of said first bending portion and whose dimension in the longitudinal direction of said insertion member is smaller than that of the first bending portion, the second bending portion being bendable in accordance with the bending operation by a user; wherein a bending angle said first bending portion assumes when bent is set and a bending angle said second bending portion assumes when bent is set are determined so that when said second bending portion is bent by an angle θ and said first bending portion is bent by an angle θ+90°C or more in a direction opposite to the direction in which said second bending portion is bent, if the distal portion of said insertion member is angled substantially perpendicularly to the longitudinal direction of said insertion member, the distal portion of said insertion member will be distanced from a tangent to the longitudinal direction of said insertion member.
6. An endoscope comprising:
a first bending portion that is the distal portion of an elongated insertion member; a second bending portion that is located at the proximal end of said first bending portion and whose dimension in the longitudinal direction of said insertion member is smaller than the dimension of the first bending portion therein; a first control portion included in a hand-held unit proximal to said insertion member and used to bend said first bending portion; and a second control portion included in the hand-held unit proximal to said insertion member and used to bend said second bending portion; wherein a bending angle said first bending portion assumes when bent is set and a bending angle said second bending portion assumes when bent is set are determined so that when said second bending portion is bent by an angle θ and said first bending portion is bent by an angle θ+90°C or more in a direction opposite to the direction in which said second bending portion is bent, and when the distal portion of said insertion member is angled substantially perpendicularly to the longitudinal direction of said insertion member, the distal portion of said insertion member will be distanced from a tangent to the longitudinal direction of said insertion member.
2. The endoscope according to
said first bending portion can be bent in four directions substantially perpendicular to the longitudinal direction of said insertion member; and said second bending portion can be bent in at least two directions perpendicular to the longitudinal direction of said insertion member.
3. The endoscope according to
4. An endoscope according to
5. The endoscope according to
7. The endoscope according to
said first bending portion is bendable in four directions substantially perpendicular to the longitudinal direction of said insertion member; and said second bending portion is bendable in at least two directions perpendicular to the longitudinal direction of said insertion member.
8. The endoscope according to
9. The endoscope according to
10. The endoscope according to
11. The endoscope according to
12. The endoscope according to
13. The endoscope according to
said first control portion is located so that when said hand-held unit is held, said first control portion will lie within reach of a finger of the hand with which said hand-held unit is held; and said second control portion is located so that when said hand-held unit is held, said second control portion will lie beyond reach of a finger of the hand with which said hand-held unit is held.
14. The endoscope according to
15. The endoscope according to
16. The endoscope according to
said second control portion is arranged so that when said hand-held unit is held, said second control portion will lie beyond reach of a finger of the left hand with which said hand-held unit is held, and will be manipulated with a finger of the right hand.
17. The endoscope according to
18. The endoscope according to
19. The endoscope according to
20. The endoscope according to
21. The endoscope according to
22. The endoscope according to
25. The endoscope according to
26. The endoscope according to
the second bending portion is bendable under the control of a second control portion.
27. The endoscope according to
28. The endoscope according to
the second control portion is arranged so that when the hand-held unit is held, the second control portion will lie beyond reach of a finger of the hand with which the hand-held unit is held.
29. The endoscope according to
the second bending portion can be bent in at least two directions perpendicular to the longitudinal direction of the insertion member.
30. The endoscope according to
31. The endoscope according to
32. The endoscope according to
33. The endoscope according to
34. The endoscope according to
35. The endoscope according to
36. The endoscope according to
38. The endoscope according to
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This application is based upon and claims the benefit of priority from the prior Japanese Patent Application No. 2000-302470, filed on Oct. 2, 2000 and No. 2001-232166 filed on Jul. 31, 2001 in Japan, the entire contents of which are incorporated herein by reference.
1. Field of the Invention
The present invention relates to an endoscope, or more particularly, to an endoscope having two bending portions of a first bending portion and a second bending portion.
2. Description of the Related Art
Endoscopes have an elongated insertion member thereof inserted into a three-dimensionally complexly tortuous and narrow lumen of the stomach, the intestine, or any other organ of a living tissue, or a three-dimensionally complexly tortuous and narrow hollow of a machine in conformity with the shape of the lumen or hollow. The insertion member must therefore be angled three-dimensionally finely.
For example, an endoscope described in Japanese Examined Patent Application Publication No. 5-16857 has two bending portions of a first bending portion and a second bending portion. The first bending portion is the distal portion of an elongated insertion member and has a plurality of joint pieces concatenated so that the joint pieces can rotate freely. The second bending portion is located at the proximal end of the first bending portion. A hand-held unit having a control section that is used to bend the first bending portion and second bending portion has an angling mechanism. The sole angling mechanism enables selective bending of the first bending portion and second bending portion.
However, when the insertion member of an endoscope has two bending portions, the lengths of the bending portions have a significant meaning.
For example, assume that a narrow lumen such as the lumen of the large intestine is observed. In this case, if the second bending portion that is the proximal portion is longer, when the second bending portion is bent, the bending portion including the first and second bending portions is entirely largely moved. It is therefore hard to finely adjust the position of the distal part of the endoscope. This eventually poses a problem that observation is hard to achieve.
For example, when the cardia of the stomach and its surroundings are observed by viewing the face of the cardia, the first bending portion is largely bent in an Up direction and the second bending portion is bend in a Down direction. The distal part of an endoscope may thus be made to approach the cardia. When the second bending portion is long, although the second bending portion has not fully come out of the esophagus, the whole bending portion including the first and second bending portions must be bent. It is therefore hard to bend the second bending portion. This results in unsuccessful observation.
The present invention attempts to break through the foregoing situation. The present invention aims to provide an endoscope capable of offering improved ease of observation with a second bending portion thereof bent and with a distal portion of an insertion member thereof faced a desired position.
Accordingly, an object of the present invention is to provide an endoscope offering improved ease of observation with a distal portion of an insertion member thereof faced a desired position.
Another object of the present invention is to provide an endoscope having two bending portions that can be bent independently of each other, and offering ease of bending of the same level as that an endoscope having one bending portion offers.
Still another object of the present invention is to provide an endoscope offering excellent maneuverability and making it possible to readily achieve accurate observation or treatment.
According to the present invention, there is provided an endoscope having a first bending portion and a second bending portion. The first bending portion is the distal portion of an elongated insertion member. The second bending portion is located at the proximal end of the first bending portion. The dimension of the second bending portion in the longitudinal direction of the insertion member is smaller than the dimension of the first bending portion therein.
According to the present invention, there is provided an endoscope having a first bending portion, a second bending portion, a first control member, and a second control member. The first bending portion is the distal portion of an elongated insertion member. The second bending portion is located at the proximal end of the first bending portion, and the dimension of the second bending portion in the longitudinal direction of the insertion member is smaller than the dimension of the first bending portion therein. The first control member is included in a hand-held unit proximal to the insertion member and used to bend the first bending portion. The second control member is included in the hand-held unit proximal to the insertion member and used to bend the second bending portion.
Other features of the present invention and the advantages thereof will be fully apparent from the description below.
FIG. 3A and
FIG. 16A and
FIG. 18A and
An embodiment of the present invention will be described with reference to the drawings below.
As shown in
A VTR deck, a video printer, a video disk drive, an image file recording apparatus, or the like, not shown, can be connected to the video processor 4.
The endoscope 2 has an elongated insertion member 11 that is inserted into a region to be observed. A hand-held unit 12 is located at the proximal end of the insertion member 11. The hand-held unit 12 includes a control section 12a that is used to bend first and second bending portions that will be described later.
A universal cord 13 is extended from the lateral side of the hand-held unit 12. A signal cable that is routed to the image pick-up means which is not shown and a light guide over which illumination light is propagated are contained in the universal cord 13.
A connector 14 is attached to the end of the universal cord 13. The connector 14 is coupled to the light source apparatus 3 and connected to the video processor 4 such that it can be connected and disconnected freely.
A distal part 21 is located at the distal end of the insertion member 11. A bending portion 22 capable of freely bending is located at the proximal end of the distal part 21. A flexible-tube 23 is located at the proximal end of the bending portion 22. The flexible tube 23 is formed with an elongated member that is soft and tubular.
An image pick-up unit in which a solid-state image pick-up device that is not shown, such as, a CCD and a circuit board for driving the solid-state image pick-up device are incorporated is included as the image pick-up means in the distal part 21. The distal end of the light guide is extended to the distal part 21, whereby illumination light propagated from the light source apparatus 3 is radiated to a region to be observed in a body cavity. The region to be observed is thus illuminated.
The bending portion 22 is composed of two bending portions, that is, a first bending portion 24 that is the distal half of the bending portion 22 and a second bending portion 25 that succeeds the first bending portion 24.
To begin with, the structure of the bending portion 22 will be described in conjunction with
As shown in
The bending braid 32 and bending rubber 33 may be used to sheathe the bending portion 22 composed of the first bending portion 24 and second bending portion 25 over the whole length of the bending portion 22. Otherwise, the first bending portion 24 and second bending portion 25 may be sheathed with the bending braid 32 and bending rubber 33 independently of each other.
First wires 34 used to pull and bend the first bending portion 24 are extended from the distal end of the first bending portion 24.
Second wires 35 used to pull and bend the second bending portion 25 are extended from the distal end of the second bending portion 25.
The first wires 34 are passed through first coil pipes 36 fixed to the distal end of the second bending portion 25, and thus routed to a first control subsection 42, which will be described later, by way of the insertion member 11.
Moreover, the second wires 35 are passed through second coil pipes 37 fixed to the distal end of the flexible tube 23, and thus routed to a second control subsection 44, which will be described later, by way of the insertion member 11.
Furthermore, the thickness of the portion of the bending rubber 33 with which the second bending portion 25 is sheathed is smaller than the thickness of the portion thereof with which the first bending portion 24 is sheathed. Consequently, the second bending portion of the bending portion 22 is more easily bent. Even if a larger number of built-in components must be put in the second bending portion 25, the outer diameter of the second bending portion 25 need not be increased. The ease of bending characterizing the bending portion 22 will therefore not deteriorate.
Generally, when the bending portion 22 is bent, a larger load is often imposed on the second bending portion 25 than on the first bending portion 24. This is because the second bending portion 25 accommodates a larger number of built-in components.
For this reason, the bending pieces 31 constituting the second bending portion 25 of the bending portion 22 are, as shown in FIG. 3A and
In other words, bending pieces 31b used to construct the second bending portion 25 of the bending portion 22 as shown in
Consequently, even when a larger magnitude of force is applied to the second bending portion 25 than to the first bending portion 24, the bending pieces 31 constituting the second bending portion 25 hardly deform. Thus, a bending angle the second bending portion 25 assumes when bent is set will not get smaller than a bending angle it assumes in an initial state.
Moreover, coil pipes used as the first coil pipes 36 and second coil pipes 37 are made by, as shown in
According to the present embodiment, the control section 12a of the hand-held unit 12 consists of the first control subsection 42 and second control subsection 44. The first control subsection 42 is used to bend the first bending portion 24. The second control subsection 44 is used to bend the second bending portion 25. Owing to the structure, the first bending portion 24 and second bending portion 25 can be bent independently of each other.
The first control subsection 42 includes, as shown in
The second control subsection 44 includes, as shown in
The control section 12a has an electric switch subsection 43 that includes remote switches 43a used to instruct the video processor 4 to freeze or unfreeze a view image.
The angling knob 42a is a knob used to bend the first bending portion 24 in Up and Down directions. The angling knob 42a' is a knob used to bend the first bending portion 24 in Right and Left directions.
The first locking lever 42b is a lever used to lock the angling knob 42a at a desired angular position. The first locking lever 42b' is a knob used to lock the angling knob 42a' at a desired angular position.
Furthermore, the first control subsection 42 includes an aeration/perfusion button 42c used to instruct aeration or perfusion and a suction button 42d used to instruct suction.
The endoscope 2 having the foregoing components is used to perform endoscopic examination.
In general, an operator holds, as shown in
In this case, for example, the hand-held unit 12 is borne with the root of the thumb of the left hand and the ring finger and little finger of the left hand. The angling knob 42a and second angling lever 44a are manipulated using the thumb. The index finger and middle finger are also used to manipulate the angling knob 42a and second angling lever 44a when these fingers are not manipulating the remote switches 43a and the buttons including the aeration/perfusion button 42c and suction button 42d.
When an operator wants to bend the first bending portion 24, the operator bears the hand-held unit 12 with the root of the thumb of the left hand and the ring finger and little finger thereof. The operator then manipulates the angling knob 42a using the thumb, index finger, or middle finger thereof. At this time, the angling knob 42a lies within reach of the thumb, index finger, or middle finger.
Moreover, when an operator wants to bend the second bending portion 25, the operator manipulates the second angling lever 44a with his/her right hand that does not hold the hand-held unit 12.
The thumb, index finger, or middle finger may be stretched to a position that is usually beyond reach of it in order to manipulate the second angling lever 44a.
When the remote switches 43a are used or endoscopic treatment is carried out, the first locking levers 42b and 42b, and the second locking lever 44b may be used to lock the angling knobs 42a and 42a, and the second angling lever 44a at desired angular positions. In this case, the thumb can be separated from the hand-held unit, and the endoscope can be manipulated with the insertion member retained in a desired bent state.
Moreover, the second control subsection 44 is separated from the first control subsection 42 with the electric switch subsection 43 between them. When the angling knob 42a is manipulated, the fingers with which the angling knob is manipulated will not come in contact with the second angling lever 44a.
The second angling lever 44a may be, as shown in the plan view of
The foregoing structure may be modified in consideration of ease with which the second angling lever 44a can be manipulated with, for example, the right hand, so that the second angling lever 44a will jut out towards the angling knobs 42 as shown in FIG. 10B and FIG. 10C.
Referring to FIG. 5 and
The axes of rotation in the first control subsection 42 and second control subsection 44 may extend parallel to each other as shown in FIG. 5. Alternatively, the axes of rotation may meet at an angle as shown in FIG. 8. Referring to
Moreover, when the second bending portion 25 is designed to be able to bend in four directions, the second control subsection 44 includes two angling knobs 44c as shown in FIG. 9. The second bending portion 25 can thus be bent in four directions.
Consequently, in the endoscope 2 in accordance with the present embodiment, the first and second bending portions 24 and 25 can be bent independently of each other. The two bending portions can be handled in the same manner as an ordinary bending portion is. The endoscope 2 of the present embodiment offers improved ease of bending.
The endoscope 2 of the present embodiment has the second control subsection 44 separated from the first control subsection 42. Consequently, when the first control subsection 42 alone is used, the second control subsection will not annoy an operator. The endoscope offers ease of bending of the same level as a normally employed endoscope having one bending portion does.
Furthermore, the endoscope 2 of the present embodiment has the second control subsection 44 and first control subsection 42 separated from each other with the electric switch subsection 43 between them. Consequently, the maneuverability offered by the endoscope will not be poorer than the maneuverability offered by an ordinary endoscope. In addition, when the first control subsection 42 and electric switch subsection 43 are used, the second control subsection 44 will not be manipulated incorrectly.
In the endoscope 2 of the present embodiment, the axes of rotation in the first control subsection 42 and second control subsection 44 meet at an angle. Consequently, when the first control subsection 42 is held with one hand and the second control subsection 44 is manipulated with the other hand, the second control subsection 44 can be manipulated easily.
The endoscope 2 in accordance with the present embodiment is an electronic endoscope having the image pick-up unit incorporated in the distal part 21 of the insertion member 11. Alternatively, the present invention may be implemented in an electronic endoscope in which an image guide that is not shown is run through the insertion member 11 and an object image propagated along the image pick-up guide is picked up by an image pick-up unit incorporated in the control section 12a. Moreover, the present invention may be implemented in a so-called optical endoscope in which an object image propagated along the image guide is viewed through an eyepiece unit mounted on the control section 12a. In any case, the endoscope has the bending portion 22 composed of the first bending portion 24 and second bending portion 25.
The present invention is not limited to the aforesaid embodiment, but can be modified in various aspects with the gist of the present invention left unchanged.
For example, as shown in
As far as observation of an intracavitary region is concerned, observing a region to be observed from the front side thereof is very helpful in a viewpoint of producing a clear image devoid of deformation.
When an endoscope has the same structure as the aforesaid one, that is, the elongated insertion member 11 has the bending portion 22 composed of the first bending portion 24 and second bending portion 25, the first bending portion 24 and second bending portion 25 are bent independently of each other. Thus, the distal part 21 of the insertion member can be faced a region to be observed.
For example, the insertion member 11 may be in close contact with the intracavitary wall as shown in FIG. 21. In this case, the second bending portion 25 is bent upward by an angle θ with respect to the longitudinal axis of the insertion member 11. At the same time, the first bending portion 24 is bent downwards by an angle θ+90°C with respect to the longitudinal axis of the insertion member 11. Consequently, the distal part 21 of the insertion member 11 is angled to face a region to be observed that is located on an intracavitary wall.
However, assume that the insertion member 11 is in close contact with an intracavitary wall, and that the distal part 21 of the insertion member is faced the intracavitary wall. In this case, the distal part 21 is located near an extension of the longitudinal axis of the flexible tube 23 (which is in close contact with the intracavitary wall) of the insertion member 11. Consequently, the distal part 21 cannot have a predetermined distance from the region to be observed.
If the distal part 21 cannot be separated from a region to be observed by a predetermined distance, it is hard to observe the region to be observed during endoscopic examination. Although the predetermined distance cannot be preserved, if an attempt is made to perform endoscopic treatment, a therapeutic instrument or the like may not be able to be projected from the distal part 21 towards an intracavitary wall. Consequently, the endoscopic treatment fails.
In order to solve the above problem, it is conceivable to increase the dimension of the second bending portion 25. The second bending portion 25 is bent appropriately in order to raise the first bending portion 24 relative to the intracavitary wall, whereby the predetermined distance may be preserved. However, this structure has a drawback that the overall length of the bending portion 22 is too large.
The bending portion 22 has, as described in conjunction with
There is therefore a long-persistent demand for an endoscope that offers improved ease of observation and treatment when the distal part 21 is faced an intracavitary wall with both the first bending portion 24 and second bending portion 25 bent.
Referring to
As shown in
Referring to
The thus-structured bending portion 22 is adapted to a conventional enlarged-view endoscope 2A that has, as shown in
As shown in
Referring to
Now, when the bending portion 22 is structured as shown in
As shown in
In short, observation can be continued with the relative positions of the lesion and the distal part varied.
Furthermore, as shown in
In short, the distance between the lesion and the distal part of the endoscope can be adjusted with the distal part angled to the lesion.
As shown in FIG. 13 and
Furthermore, the bending portion 22 may be designed such that the second bending portion 25 will be shorter than the first bending portion 24 as shown in FIG. 16A. For example, when the endoscope is used to observe a tortuous lumen such as the lumen of the large intestine, even if the second bending portion 25 is bent, the second bending portion 25 will not interfere with the intestinal wall but the bending portion 22 can be entirely moved.
In contrast with
As shown in
As shown in
Now, in an endoscope shown in
As shown in
When the duodenal papilla or any other region of the duodenum is incised, the distal end of an endoscope should be made to approach obliquely for more successful treatment.
In this case, the second wires 35 to be pulled in order to bend the second bending portion 25 may be arranged as shown in
As shown in FIG. 20A and
As shown in
As far as the aforesaid endoscope whose elongated insertion member 11 has the bending portion 22 is concerned, the second bending portion 25 of the bending portion 22 is first bent. Namely, the one of the second wires 35 described in conjunction with
There is therefore a demand for an endoscope having a simple structure and having the second bending portion 25 capable of being straightened.
Referring to FIG. 22 and
As shown in
The second bending portion 25 has, similarly to the first bending portion 24, the plurality of bending pieces 31 concatenated so that the bending pieces can rotate freely. The bending pieces 31 are sheathed with the bending braid 32. The bending braid 32 is coated with a resilient resin 61 such as polyester which is the same resin as that adopted for the flexible tube 23.
Consequently, the second bending portion 25 has the bending braid 32 coated with the resilient resin 61 that is the same resin as that adopted for the flexible tube 23. Therefore, the second bending portion 25 that has been bent can be straightened by merely slackening one of the second wires 35. Namely, the second wire 35 to be slackened is a second wire that has been pulled in order to bend the second bending portion 25 in a direction that runs externally parallel to the second wire.
Moreover, the second wires 35 used to bend the second bending portion 25 may lie, as shown in
As described in conjunction with
The second bending portion 25 has the same structure as, for example, the flexible tube 23 (for example, as shown in
Consequently, when the second wires 35 are not tensioned, the second bending portion 25 is automatically straightened. Only one of the second wires 35 can therefore be used to bend or straighten the second bending portion 25. Herein, a position of the second wire defines one direction in which the second bending portion 25 can be bent.
The present invention is not limited to the aforesaid embodiment, but can be modified in various aspects with the gist of the invention left unchanged.
As described so far, according to the present invention, a second bending portion is made shorter than a first bending portion. This results in an endoscope that can be angled readily while being unaffected by the state of a lumen into which the endoscope is inserted.
According to the present invention, it is apparent that a wide range of different embodiments can be formed based on the invention without a departure from the spirit and scope of the invention. The present invention is limited to the appended claims but not restricted to any specific embodiment.
Nakamura, Toshio, Ogura, Takeshi, Kaiya, Haruhiko, Hamazaki, Masanori
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